Title :
A 12-bit 75-MS/s pipelined ADC using open-loop residue amplification
Author :
Murmann, Boris ; Boser, Bernhard E.
Author_Institution :
Berkeley Sensor & Actuator Center, Univ. of California, Berkeley, CA, USA
Abstract :
Precision amplifiers dominate the power dissipation in most high-speed pipelined analog-to-digital converters (ADCs). We propose a digital background calibration technique as an enabling element to replace precision amplifiers by simple power-efficient open-loop stages. In the multibit first stage of a 12-bit 75-MSamples/s proof-of-concept prototype, we achieve more than 60% residue amplifier power savings over a conventional implementation. The ADC has been fabricated in a 0.35-μm double-poly quadruple-metal CMOS technology and achieves typical differential and integral nonlinearity within 0.5 LSB and 0.9 LSB, respectively. At Nyquist input frequencies, the measured signal-to-noise ratio is 67 dB and the total harmonic distortion is -74 dB. The IC consumes 290 mW at 3 V and occupies 7.9 mm2.
Keywords :
CMOS analogue integrated circuits; amplifiers; analogue-digital conversion; harmonic distortion; open loop systems; parameter estimation; pipeline processing; 0.35-μm double-poly quadruple-metal CMOS technology; 0.5 LSB; 0.9 LSB; 12 bit; 12-bit 75-MS/s pipelined ADC; 12-bit 75-MSamples/s proof-of-concept prototype; 3 V; 67 dB; 74 dB; CMOS analog integrated circuits; IC consumes 290 mW; Nyquist input frequencies; adaptive systems; analog-to-digital conversion; differential nonlinearity; digital background calibration technique; high-speed pipelined analog-to-digital converters; integral nonlinearity; linearization techniques; multibit first stage; open-loop residue amplification; parameter estimation; power dissipation; power-efficient open-loop stages; precision amplifiers; residue amplifier power savings; signal-to-noise ratio; total harmonic distortion; Analog-digital conversion; CMOS technology; Calibration; Distortion measurement; Frequency measurement; High power amplifiers; Power amplifiers; Power dissipation; Prototypes; Signal to noise ratio;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2003.819167
